Development of FCC Naphtha Hydrodesulfurization and Aromatization Process 被引量：1

Development of FCC Naphtha Hydrodesulfurization and Aromatization Process

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摘要 This articles refers to the development of the technology for hydrodesulfurization (HDS) and aromatization of FCC naphtha This technology adopts a catalyst with aromatization performance, which does not reduce the octane rating of gasoline in the course of HDS of FCC naphtha. Experimental results have shown that the sulfur removal rate of FCC naphtha could reach over 85%, with the RON of gasoline increased by 0.2-0.6 units, the MON increased by 1.3-1.8 units and the antiknock index of the gasoline increased by around one unit. The total C5+ liquid yield was over 95%. The activity of regenerated catalyst could be restored to be equal to that of fresh one after coke burning on the spent catalyst. This articles refers to the development of the technology for hydrodesulfurization （HDS） and aromatization of FCC naphtha This technology adopts a catalyst with aromatization performance, which does not reduce the octane rating of gasoline in the course of HDS of FCC naphtha. Experimental results have shown that the sulfur removal rate of FCC naphtha could reach over 85%, with the RON of gasoline increased by 0.2--0.6 units, the MON increased by 1.3--1.8 units and the antiknock index of the gasoline increased by around one unit, The total C5^＋ liquid yield was over 95%, The activity of regenerated catalyst could be restored to be equal to that of fresh one after coke burning on the spent catalyst.

作者 Zhu Huaxing Zhu Jianhua Liu Jinlong Sun Diancheng Gong Xuhui

机构地区 College of Chemical Engineering China University of Petroleum SINOPEC Luoyang Petrochemical Engineering Company

出处《China Petroleum Processing & Petrochemical Technology》 SCIE CAS 2005年第4期47-51,共5页 中国炼油与石油化工（英文版）

关键词 FCC gasoline catalyst： hydrodesulfurization octane number AROMATIZATION 催化裂化汽油催化剂加氢脱硫辛烷值芳构化

分类号 TE626.21 [石油与天然气工程—油气加工工程] TE624.431 [石油与天然气工程—油气加工工程]

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参考文献2

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China Petroleum Processing & Petrochemical Technology

2005年第4期

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